9

I have a scientific code that uses both sine and cosine of the same argument (I basically need the complex exponential of that argument). I was wondering if it were possible to do this faster than calling sine and cosine functions separately.

Also I only need about 0.1% precision. So is there any way I can find the default trig functions and truncate the power series for speed?

One other thing I have in mind is, is there any way to perform the remainder operation such that the result is always positive? In my own algorithm I used x=fmod(x,2*pi); but then I would need to add 2pi if x is negative (smaller domain means I can use a shorter power series)

EDIT: LUT turned out to be the best approach for this, however I am glad I learned about other approximation techniques. I will also advise using an explicit midpoint approximation. This is what I ended up doing:

const int N = 10000;//about 3e-4 error for 1000//3e-5 for 10 000//3e-6 for 100 000
double *cs = new double[N];
double *sn = new double[N];
for(int i  =0;i<N;i++){
    double A= (i+0.5)*2*pi/N;
    cs[i]=cos(A);
    sn[i]=sin(A);
}

The following part approximates (midpoint) sincos(2*pi*(wc2+t[j]*(cotp*t[j]-wc)))

double A=(wc2+t[j]*(cotp*t[j]-wc));
int B =(int)N*(A-floor(A));
re += cs[B]*f[j];
im += sn[B]*f[j];

Another approach could have been using the chebyshev decomposition. You can use the orthogonality property to find the coefficients. Optimized for exponential, it looks like this:

double fastsin(double x){
    x=x-floor(x/2/pi)*2*pi-pi;//this line can be improved, both inside this 
                              //function and before you input it into the function

    double x2 = x*x;
    return (((0.00015025063885163012*x2- 
   0.008034350857376128)*x2+ 0.1659789684145034)*x2-0.9995812174943602)*x;} //7th order chebyshev approx
1

If you seek fast evaluation with good (but not high) accuracy with powerseries you should use an expansion in Chebyshev polynomials: tabulate the coefficients (you'll need VERY few for 0.1% accuracy) and evaluate the expansion with the recursion relations for these polynomials (it's really very easy).

References:

  1. Tabulated coefficients: http://www.ams.org/mcom/1980-34-149/S0025-5718-1980-0551302-5/S0025-5718-1980-0551302-5.pdf
  2. Evaluation of chebyshev expansion: https://en.wikipedia.org/wiki/Chebyshev_polynomials

You'll need to (a) get the "reduced" argument in the range -pi/2..+pi/2 and consequently then (b) handle the sign in your results when the argument actually should have been in the "other" half of the full elementary interval -pi..+pi. These aspects should not pose a major problem:

  1. determine (and "remember" as an integer 1 or -1) the sign in the original angle and proceed with the absolute value.
  2. use a modulo function to reduce to the interval 0..2PI
  3. Determine (and "remember" as an integer 1 or -1) whether it is in the "second" half and, if so, subtract pi*3/2, otherwise subtract pi/2. Note: this effectively interchanges sine and cosine (apart from signs); take this into account in the final evaluation.

This completes the step to get an angle in -pi/2..+pi/2 After evaluating sine and cosine with the Cheb-expansions, apply the "flags" of steps 1 and 3 above to get the right signs in the values.

  • I am so glad I learned about this. I was too lazy to read the pdf but I am guessing they used the orthogonality property to decompose into ChebyshevU's. Which is what I did i.imgur.com/eSNoMYO.png – grdgfgr Aug 4 '15 at 20:43
  • Also, what sort of functions are approximated well by chebyshev polynomials? They (for sincos) seem to be quite better than pade approximants. Or does it talk about it in the pdf? – grdgfgr Aug 4 '15 at 20:50
  • Chebyshev polynomials are suitable for functions that are not "too wild". This, of course, is loose language. Think: having asymptotes, discontinuities and the like and you'll get the idea. Furthermore: the approximation should apply on a finite interval. – Bert te Velde Aug 5 '15 at 8:21
1

Just create a lookup table. The following will let you lookup the sin and cos of any radian value between -2PI and 2PI.

// LOOK UP TABLE
var LUT_SIN_COS = [];
var N = 14400;
var HALF_N = N >> 1;
var STEP = 4 * Math.PI / N;
var INV_STEP = 1 / STEP;
// BUILD LUT
for(var i=0, r = -2*Math.PI; i < N; i++, r += STEP) {
    LUT_SIN_COS[2*i] = Math.sin(r);
    LUT_SIN_COS[2*i + 1] = Math.cos(r);
}

You index into the lookup table by:

var index = ((r * INV_STEP) + HALF_N) << 1;
var sin = LUT_SIN_COS[index];
var cos = LUT_SIN_COS[index + 1];

Here's a fiddle that displays the % error you can expect from different sized LUTS http://jsfiddle.net/77h6tvhj/

EDIT Here's an ideone (c++) with a ~benchmark~ vs the float sin and cos. http://ideone.com/SGrFVG For whatever a benchmark on ideone.com is worth the LUT is 5 times faster.

  • IIRC, for a fixed error, linear interpolation allows the use of a much smaller LUT. sin and cos are very well-behaved functions. In particular, if you can fit the smaller LUT in L1 cache instead of L2, it's a lot faster. Sure, you need two LUT entries, but they're adjacent and therefore usually on the same cache line. – MSalters Aug 5 '15 at 11:19
  • @MSalters - The difference between L1 and L2 cache hits on a modern processor are about 2.5x (4 cycles vs 10 cycles), I would think the logic to perform the interpolation would make up the difference. Also, if you were really constraining the LUT to say -pi/2..pi/2 then you'd also have the extra overhead of extrapolating the final sign. But if you have code on hand feel free to paste it into the ideone I linked. – Louis Ricci Aug 5 '15 at 12:52
  • Did some micro benchmark. 0.43 seconds sinf + cosf, 0.24 seconds lookup table (257 values from -PI/2 to +PI/2 for both sine and cosine, linear interpolation), 0.16 seconds XMScalarSinCos (the time is for 10M calculations). XMScalarSinCos uses high-degree polynomial approximation. As you see, on modern hardware floating-point multiplications and additions are faster than even L1 cache lookups. – Soonts Jul 25 '16 at 15:43
  • @Soonts - SIMD (SSE instruction sets) are very impressive. And while I can't deny that in the general case the XM* (or ay other suitable SSE math libs) functions are faster than a LUT, the bottleneck is not the L1 or L2 cache lookup. On a modern CPU an L1 cache read is ~4 cycles (L2 ~10 cycles) the XM* function is roughly ~~30cyles; I'd wager the bottleneck in the LUT code is the overhead massaging the fp value into an int index (this code probably uses the slower x87 fp instructions depending on compiler optimization settings), and possible misalignment of the memory that makes up the LUT. – Louis Ricci Jul 26 '16 at 12:12
0

One way to go would be to learn how to implement the CORDIC algorithm. It is not difficult and pretty interesting intelectually. This gives you both the cosine and the sine. Wikipedia gives a MATLAB example that should be easy to adapt in C++.

Note that you can augment speed and reduce precision simply by lowering the parameter n.


About your second question, it has already been asked here (in C). It seems that there is no simple way.

  • Looks promising. I would still be interested in learning (if it is possible) to do float remainder operation which gives only positive values. – grdgfgr Aug 4 '15 at 16:24
  • I'm not sure I understand what you mean. – styko Aug 4 '15 at 16:26
  • When I tried to implement a power series, I wanted to use sine's periodicity of 2pi. But fmod/remainder operation will give -pi when the input is fmod(-3pi,2pi). This makes means the power series I tried to implement should be valid between (-2pi,2pi) or I should use an extra if condition to turn -pi into +pi. I was wondering if I could make it so that fmod always outputs positive remainder – grdgfgr Aug 4 '15 at 16:31
  • Answer above. Will you have problems converting the MATLAB code into C++? – styko Aug 4 '15 at 16:55
  • This is a link-only answer, effectively, as the answer is worthless without the link. – Puppy Aug 4 '15 at 18:59
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You can also calculate sine using a square root, given the angle and the cosine.

The example below assumes the angle ranges from 0 to 2π:

 double c = cos(angle);
 double s = sqrt(1.0-c*c);
 if(angle>pi)s=-s;
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For single-precision floats, Microsoft uses 11-degree polynomial approximation for sine, 10-degree for cosine: XMScalarSinCos. They also have faster version, XMScalarSinCosEst, that uses lower-degree polynomials.

If you aren’t on Windows, you’ll find same code + coefficients on geometrictools.com under Boost license.

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